Joachim Höchel

Development of heart rate irregularities in chick embryos

Heart rate (HR) irregularities in chick embryos were defined as large fluctuations (>10 beats/min) comprising irregular, brief deceleration and/or acceleration of instantaneous HR (IHR). IHR was determined directly from the arterial blood pressure while adequate gas exchange was maintained through an eggshell and chorioallantoic membrane. Five embryos were examined on each day from day 11 to day 19 of incubation. Baseline HR was stable until day 12-13, and on around day 13-14 transient, rapid deceleration of HR (termed V pattern) began to appear, with a subsequent increase in its frequency and magnitude. The acceleration patterns (lambda, avian omega, and periodic patterns) appeared later, and the IHR became increasingly irregular, with additional, spontaneous deceleration and acceleration patterns toward hatching. Additional experiments with intravenous administration of autonomic drugs clearly showed that rapid deceleration of HR was mediated by parasympathetic nervous function but did not always show clear relations of sympathomimetic and sympathetic blocking agents to the acceleration patterns.Heart rate (HR) irregularities in chick embryos were defined as large fluctuations (>10 beats/min) comprising irregular, brief deceleration and/or acceleration of instantaneous HR (IHR). IHR was determined directly from the arterial blood pressure while adequate gas exchange was maintained through an eggshell and chorioallantoic membrane. Five embryos were examined on each day from day 11 to day 19 of incubation. Baseline HR was stable until day 12-13, and on around day 13-14 transient, rapid deceleration of HR (termed V pattern) began to appear, with a subsequent increase in its frequency and magnitude. The acceleration patterns (lambda, avian omega, and periodic patterns) appeared later, and the IHR became increasingly irregular, with additional, spontaneous deceleration and acceleration patterns toward hatching. Additional experiments with intravenous administration of autonomic drugs clearly showed that rapid deceleration of HR was mediated by parasympathetic nervous function but did not always show clear relations of sympathomimetic and sympathetic blocking agents to the acceleration patterns.

Biological rhythms in birds--development, insights and perspectives.

The aim of this review is to show that probably the internal clock of precocial birds is imprinted in the prenatal period by exogenous factors (zeitgeber). The activity of organ functions occurs early during embryonic development, before this function is ultimately necessary to ensure the survival of the embryo. Prenatal activation of some functional systems may have a training effect on the postnatal efficiency. The development of physiological control systems is influenced by endogenous and exogenous factors during the late prenatal and early postnatal period: epigenetic adaptation processes play an important role in the development of animals; they have acquired characteristics which are innated but not genetically fixed. As a rule, the actual value during the determination period has a very strong influence on the set-point of the system. This will be explained using the example of thermoregulation. It is shown in detail that it seems to be possible to imprint the prenatal development of circadian rhythms by periodic changes of the light-dark cycle but not by rhythmic influence of acoustic signals. Altogether, there are more questions open than solved concerning the perinatal genesis of circadian rhythms in birds. Topics are given for the future research.

Non-invasive determination of instantaneous heart rate in developing avian embryos by means of acoustocardiogram

Previous noninvasive studies of the mean heart rate of embryonic birds have prompted an investigation into the instantaneous heart rate (IHR), which may be informative in developmental studies of cardiac rhythm. Using the acoustocardiogram (ACG), a noninvasive, long-term measuring system for embryonic IHR is developed, and the IHR in chickens during the last half of embryonic development is determined. The system, which uses a micro-computer, samples the ACG at a frequency of 50 Hz, restores the ACG wave by sinc function and calculates the IHR with an error in accuracy of less than 1 beat min−1. It was found that characteristic, transient bradycardia begins to appear late in the second week of incubation, and, with the additional development of transient tachycardia, the embryonic cardiac rhythm becomes more arrhythmic towards hatching. Simultaneous measurements of IHR with somatic movements showed no relationship between arrhythmia and embryonic activities. This system is useful, providing new evidence on long-term IHR developmental patterns.

Cardiac rhythms in chick embryos during hatching

Avian embryos develop within a hard eggshell which permits the measurement of heart rate while maintaining an adequate gas exchange through the chorioallantoic membrane. Heart rate has been determined from cardiogenic signals detected either noninvasively, semi-invasively or invasively with various transducers. Firstly, we reviewed these previously-developed methods and experimental results on heart rate fluctuations in prenatal embryos. Secondly, we presented new findings on the development of heart rate fluctuations during the last stages of incubation, with emphasis on the perinatal period, which remained to be studied. Three patterns of acceleration of the instantaneous heart rate were unique to the external pipping period: irregular intermittent large accelerations, short-term repeated large accelerations and relatively long-lasting cyclic small accelerations. Besides these acceleration patterns, respiratory arrhythmia, which comprimised oscillating patterns with a period of 1-1.5 s, appeared during the external pipping period. Furthermore, additional oscillating patterns with a period of 10-15 min were found in some externally pipped embryos.

Cardiac rhythms in developing chicks

Instantaneous heart rate (IHR) of chicks was determined by electrocardiogram measured non-invasively from the day of hatch to day 6 for continuity of investigation of HR fluctuations from embryos and for ascertainment of HR diurnal rhythms. In Experiment I, IHR was determined for 1-h periods twice a day, in daytime and at night, to investigate development of heart rate fluctuations (variability and irregularities). Chick IHR was substantially more arrhythmic than embryonic HR and spontaneous acceleration dominated HR fluctuations. Chick HR fluctuations were categorized into three types; [1] Type I as a widespread baseline HR (20-50 bpm) due to respiratory arrhythmia, with a mean oscillatory frequency of 0.74 Hz (range 0.4-1.2 Hz); [2] Type II as low frequency oscillations of baseline HR, at a mean of 0.07 Hz (range 0.04-0.10 Hz), and [3] Type III as non-cyclic irregularities, dominated by frequent transient accelerations. In Experiment II, continuous measurements of HR were made under conditions of a natural photoperiod, thermoneutrality and with feed available throughout the first week after hatching and circadian rhythms of HR were ascertained. HR was very variable in the daytime (250-500 bpm), due in part to feeding and activity, and decreased to a diurnal low (200-350 bpm) at night when mean HR was relatively stable. HR fluctuations persisted throughout the diurnal cycle.

A method for noninvasive, long-term recording of the avian embryo heart rate

A technique for obtaining a noninvasive electrocardiogram (ECG) from avian embryos is described. Accounts of electronic signal processing and computer-aided long-term recording are included. Furthermore, an algorithm is demonstrated for extracting the relevant information on heart rate from noisy data samples. The method provides the basis for monitoring the heart rate of the avian embryo on different time scales and under different influences.

Development of heart rate responses to acoustic stimuli in Muscovy duck embryos

Heart rate (HR) of Muscovy duck embryos (Cairina moschata f. domestica) was continuously recorded from the 21st day of incubation (E21) until hatching (E35). During that period, embryos were exposed to different acoustic stimuli (species-specific maternal and duckling calls, music, rectangular and sine waves, white noise). Sudden HR changes occurred at the onset of acoustic stimulation (on-response), as well as spontaneously. From E27 onwards, the response rate was significantly higher than the rate of spontaneous HR changes. The on-response rate increased further until E30. Most responses were elicited by maternal calls and music, but rarely by duckling calls. On-responses could be classified into: HR increase (36.4%), HR decrease (37.9%) and an increase in instantaneous HR variability (23.2%). The increase in HR variability occurred only in response to sounds, but not spontaneously. HR increases were mainly observed when the baseline HR was lower than the long-term HR trend. On-response duration was no longer than 3 min in 90% of all observations. The hourly mean HR and standard deviation did not change, even during phonoperiods composed of several sound patterns and lasting several hours. We conclude that Muscovy duck embryos are able to perceive exogenous acoustic stimuli, and that the acousto-sensory-->cardiac axis is functional from E27.

Development of heart rate rhythmicity in Muscovy duck embryos

The heart rate (HR) of Muscovy duck embryos (Cairina moschata f. domestica) was continuously recorded from as early as the 21st day of incubation (D21) until hatching (D34/35). The aim of the study was to investigate the influence of phonoperiods consisting of different acoustic stimuli on the course of HR and the development of HR periodicities during this period. Incubation was carried out at a constant temperature and in constant darkness. Until D25 HR was dominated by decelerative fluctuations only, indicating a main input from the parasympathetic system on the heart. Later sympathetic influences increased progressively. HR periodicity was investigated by means of chi 2-periodogram and fast Fourier transformation. Between D26 and D30 statistically significant and stable HR periodicities developed gradually. They had periods in the range from 5 to 38 h. Ultra-, circa- and infradian rhythms (< 20, 24 +/- 4 and > 28 h, respectively) occurred in parallel in some cases in the same embryo. The for the HR course important periods were dissimilar between individual embryos and had different intensities. There was no indication that acoustic stimulation (phonoperiods) had any effect on the development of HR periodicities.

Ontogeny of heart rate responses to exogenous melatonin in Muscovy duck and chicken embryos.

One of the major physiological effects of melatonin is coupling the internal clock with different organ functions. Despite the long list of functional responses to melatonin discovered in the past, it has been unclear when responsiveness to melatonin develops during ontogeny. The aim of the present study was therefore to investigate in Muscovy duck and chicken embryos, when they start to exhibit heart rate (HR) changes to exogenous melatonin. HR was recorded continuously in Muscovy duck embryos from day 24 of incubation (D24) and in chicken embryos from D17 until hatching. Every day four doses of 10 microg melatonin were injected into each egg at 30 min intervals. In Muscovy duck embryos HR responses to melatonin were first observed on D25; from D27 all embryos responded. In all cases HR decreased immediately after the injection. HR deviation from baseline values and duration of decreased HR period increased during the experimental period. Chicken embryos showed similar responses as Muscovy ducks from D17 onwards; from D18 the response rate was 100%. On D19 dose-response data revealed a partial responsiveness to exogenous melatonin at doses of 0.1 to 1 ng and full responsiveness from 10 ng to 10 microg. The time of the first occurrence of HR responses to melatonin coincides with published results on the start of periodic pineal melatonin secretion. These data suggest that the output signal of the avian internal clock, periodic plasma melatonin fluctuations, could result in periodic cardiac function already prenatally in these two avian species.